ライフサイエンスコーパス: light absorption

1 have large bandgaps that afford weak visible-light absorption.

2 ayer MoS2 and water photoionization-enhanced light absorption.

3 Kagome (kgm) lattice and show strong visible light absorption.

4 ed in a back subcell, which further enhances light absorption.

5 eaching an electronically excited state upon light absorption.

6 electronic structure changes that occur upon light absorption.

7 or photocathode initiated by molecular-level light absorption.

8 re field produced by the near-infrared laser light absorption.

9 , will hamper a C4 cycle via insufficient BS light absorption.

10 of the metal electrodes due to differential light absorption.

11 s, which arises primarily from the increased light absorption.

12 ncreased mechanical stability; and decreased light absorption.

13 han 1 eV can transfer electrons to PCBM upon light absorption.

14 ble bond undergoing a Z/E isomerization upon light absorption.

15 bution of NP to wood burning brown carbon UV light absorption.

16 p to measure the sample expansion induced by light absorption.

17 ing as miniature optic fibres, enhancing the light absorption.

18 nly 1.85 eV, which matches well with visible light absorption.

19 f hygroscopic growth of ambient particles on light absorption.

20 s involved in the deactivation cascade after light absorption.

21 ere analyzed for spectrally-resolved visible light absorption.

22 after reaching structures generated through light absorption.

23 of improved charged extraction and increased light absorption, a 120% increase in the short-circuit c

24 rotein cryptochrome is thought to host, upon light absorption, a radical pair that is sensitive to ve

25 nity, porosity, photochemical stability, and light absorption ability of the TpDTz COF enables excell

26 Light absorption across the bandgap in semiconductors is

27 ramatically enhance broadband and wide-angle light absorption across the full solar spectrum, leading

28 perovskite semiconductors combine effective light absorption, allowing detection of a wide range of

29 dS QDs and TiO(2) IOPCs widened the range of light absorption, allowing for electron injection from e

30 compared to C60, including increased visible light absorption, altered energy level structures, and v

31 Such enhancement leads to better light absorption and allows us to achieve 6.5% efficienc

32 C3 BS anatomy limits light absorption and benefits little from high pigment c

33 itting based on the integration of molecular light absorption and catalysis on oxide electrodes.

34 photosynthetic complexes and participate in light absorption and chloroplast photoprotection.

35 carbon (BrC) is an important contributor to light absorption and climate forcing by aerosols.

36 The instant light absorption and cooling at local positions by a las

37 ng, expanding the spectral cross-section for light absorption and creating considerably faster and mo

38 ever, because excess OEC material can hinder light absorption and decrease photoanode performance, it

39 is emerges as a result of a coupling between light absorption and deformation.

40 ll factor of 71.3% by virtue of the enhanced light absorption and effective carrier collection provid

41 optoelectronic crystal capable of broadband light absorption and efficient funnelling of photogenera

42 ing on far-field optical approaches based on light absorption and elastic scattering.

43 been their strong polarization dependence in light absorption and emission.

44 (radical) intermediates from the amine upon light absorption and enables the "storage" of light-ener

45 d thin-film formation leading to a broadened light absorption and enhanced film coverage on ITO/PEDOT

46 hin film material, which exhibited broadband light absorption and excellent stability in high-salinit

47 ing activity, photoanode materials with high light absorption and good charge-separation efficiency a

48 nefited cells by increasing biomass-specific light absorption and gross photosynthesis rates under lo

49 First, we measured light absorption and heat propagation in vivo, optimized

50 be effective in trapping light for enhanced light absorption and hence performance in photonic and o

51 both polarization-independent ultrabroadband light absorption and high plasmon dissipation loss.

52 that CH3NH3Sn(0.5)Pb(0.5)I3 has the broadest light absorption and highest short-circuit photocurrent

53 mbination, improve material quality, enhance light absorption and increase solubility limits of dopan

54 tion of the topographic features in terms of light absorption and isomerization process as a function

55 of animal tissue can be attributed mostly to light absorption and light scattering.

56 through the vegetated cells led to increased light absorption and lower singlet oxygen and triplet-st

57 together with photolysis, lead to diminished light absorption and lower warming effects of biomass bu

58 onal organic semiconductor that both extends light absorption and passivates surface traps in perovsk

59 Light absorption and photocatalytic activity of the resu

60 Specifically, we show that light absorption and photocurrent generation in a sub-10

61 d a trade-off amongst the characteristics of light absorption and photoprotection, which could be att

62 do increases weakly because of the decreased light absorption and practically unchanged scattering.

63 Differential light absorption and product gradient between the surfac

64 d acetylenic polymers can largely extend the light absorption and promote charge separation/transport

65 rfacial engineering further reveals enhanced light absorption and reduced trap density for improved p

66 defect states in ZnS, which lead to visible-light absorption and responded.

67 ,5-tetrazine (pytz) derivative shows visible light absorption and reversible one-electron reduction b

68 also compared to theoretical calculations of light absorption and scattering from simulated particle

69 ces that can enhance and effectively control light absorption and scattering processes.

70 The measurement of light absorption and scattering properties of biological

71 However, light absorption and scattering significantly prevents p

72 bility scaling exponent, hygroscopicity, and light absorption and scattering.

73 echnologically useful properties of complete light absorption and strong field enhancement.

74 uding more favorable energy levels, enhanced light absorption and stronger intermolecular packing.

75 orks in contrast to traditionally considered light absorption and structural photonics.

76 e pairs are produced in the MoS2 layer after light absorption and subsequently separated across the l

77 state ((5)MLCT) can be accessed via visible light absorption and that the thermalized (5,7)MLCT is l

78 stituent was responsible for higher rates of light absorption and the environmentally relevant pK(a).

79 P nanorods gave rise to the enhanced visible light absorption and the greatly accelerated photoinduce

80 sources were the primary contributors to BrC light absorption and they were moderately absorbing.

81 confinement in radial dimensions for tunable light absorptions and bulk like carrier transport in the

82 n-vacancy concentration (8.7%) exhibits high light-absorption and good charge-separation capabilities

83 thesizability, corrosion resistance, visible-light absorption, and compatibility of the electronic st

84 films, processes such as charge conduction, light absorption, and emission are governed not only by

85 ng two changes known to cause a red-shift in light absorption, and is favored in blackwater lakes but

86 stantially when the leaf center is warmed by light absorption, and more so under high humidity.

87 iple processes connected with light sensing, light absorption, and pigment binding within the thylako

88 ies due to the large contact area, efficient light absorption, and rapid charge separation and transp

89 es in LAI have little impact on total canopy light absorption; and because leaf quality has a greater

90 and evaporation in the mesoporous wood, high light absorption ( approximately 99%) within the surface

91 We also find a strong CT transition in light absorption as well as in photo- and electrolumines

92 Contrary to earlier reports, the visible light absorption at 1.8 eV ( approximately 688 nm) is du

93 cating that these particle types had minimal light absorption at 355 nm.

94 timated to explain 29 +/- 15% of average BrC light absorption at 405 nm (BrC Abs(405)) measured in th

95 ls, while lutein was quantified with visible light absorption at 450 nm.

96 ter-soluble and bioavailable and demonstrate light absorption at multiple wavelengths.

97 r transport through spatially redistributing light absorption at the active layer of devices.

98 can be greatly enhanced due to the improved light absorption, better wettability, local ordering str

99 Middle ear fluid shows strong light absorption between 1,400 and 1,550 nm, enabling st

100 We present a trade-off for light absorption between BS pigment concentration and sp

101 Extending light absorption beyond 800 nm into the NIR should incre

102 , and F(v) /F(m) in hydrogels with identical light absorption but different degrees of light scatteri

103 tuating light had thinner leaves, lower leaf light absorption, but maintained similar photosynthetic

104 omatic formulas exhibit much higher rates of light absorption, but only slightly higher rates of trip

105 The spectral dependence of light absorption by atmospheric particulate matter has m

106 Recent global models estimate that light absorption by brown carbon (BrC) in several region

107 onyl-AS-amine reactions of </= 10% of global light absorption by brown carbon.

108 aethalometer and account for 4 +/- 2% of UV light absorption by brown carbon.

109 The results indicate that light absorption by charge-transfer states or by (aromat

110 initial event in oxygenic photosynthesis is light absorption by chlorophylls (Chls), carotenoids, an

111 Since light absorption by extracellular medium increases when

112 ethylsiloxane matrix, we show that efficient light absorption by GNPs and subsequent energy transduct

113 The cry1 photocycle is initiated by light absorption by its FAD chromophore, which is most l

114 Light absorption by molecules creates a thermally induce

115 henomena create colour: spectrally selective light absorption by pigments and dyes(1,2), material-spe

116 Light absorption by PSII leads to the production of exci

117 and couples directly to GPCR activation upon light absorption by rhodopsin.

118 onversion from dark to signaling states upon light absorption by the chromophore.

119 pectral response measurements supported that light absorption by the covalently bound photoacids was

120 whole chain of energy flow that starts from light absorption by the individual nanocrystals and subs

121 easing the optical path length and therefore light absorption by the melanin.

122 mpounds that account for >70% of the overall light absorption by the MG+AS system in the 300-500 nm r

123 Light absorption by the N-terminal photosensory core mod

124 It forms on the microsecond time scale after light absorption by the oxidized state.

125 core/shell PNCs and observation of enhanced light absorption by the perovskite CsPbCl(3) shell of th

126 rkable efficiency is attributed to maximized light absorption by the thick active layer and minimized

127 The total rate of light absorption by the water samples (R(a)), the rates

128 Rf,T and the total rate of light absorption by the water samples (Ra) increased wit

129 rthern Chile, our measurements indicate that light-absorption by impurities in snow was dominated by

130 Light absorption can trigger biologically relevant prote

131 ve strategy that allows cells to balance the light absorption capabilities of photosystems I and II u

132 y zeaxanthin, and a major down-regulation of light absorption capacity by decreasing the chlorophyll

133 ally stable EC fractions that exhibit strong light absorption characteristics.

134 s with suitable properties in all aspects of light absorption, charge separation and transport, and c

135 ocesses leading to catalytic activity, i.e., light absorption, charge separation, transfer of charges

136 We report on the interplay between light absorption, charge transfer, and catalytic activit

137 By separating the functions of light absorption, charge transport and catalysis between

138 asts, which colocalize molecules involved in light absorption, charge transport and catalysis to crea

139 nge current density-to account for imperfect light absorption, charge transport and catalysis.

140 Upon light absorption, chromophoric DOM (CDOM) can sensitize

141 Substantial increase of BrC light absorption coefficient was observed during the nig

142 f nitrogen, and black carbon (as measured by light absorption coefficient) in six U.S. metropolitan r

143 nvasive imaging modality that depends on the light-absorption coefficient of the imaged tissue and th

144 Their high light absorption coefficients and long diffusion lengths

145 graphitized CDs show significantly enhanced light absorption compared to amorphous CDs (a-CD) yet un

146 h monolayer BiI3 nanosheet leads to enhanced light absorption compared to that in pure monolayer BiI3

147 C, in particular nitrophenols, are important light absorption contributors of biomass burning organic

148 Upon light absorption, dCRY undergoes a conformational change

149 ater than 50 nm, which induced an additional light absorption depression around 13.89 mum wavelength.

150 The discrete and random nature of light absorption dictates that, when photons are scarce,

151 ent environment or coordination with dynamic light absorption dramatically decreases estimation accur

152 metallic" oxide couples exhibit strong solar-light absorption driven by the unique electronic structu

153 Light absorption due to the Localized Surface Plasmon Re

154 cids instead of a prosthetic chromophore for light absorption during UV-B photoreception.

155 al phylogenetic trends in factors modulating light absorption (effective cross-section, reaction cent

156 film antireflection coating, which increases light absorption efficiency.

157 r splitting because of its multiple roles in light absorption, electrocatalysis, and corrosion protec

158 e various aspects of a photocatalytic cycle: light absorption, electron/hole transport, band edge ali

159 does not participate as a chromophore in the light-absorption/emission phenomenon.

160 ing 2D materials have demonstrated efficient light absorption, enabling large responsivity in photode

161 icon at wafer scales that achieved over 160% light absorption enhancement from 800 to 1,200 nm.

162 (metal)-shell (dielectric) nanoparticles for light absorption enhancement in thin film Si solar cells

163 electric field for high-efficiency broadband light absorption, exciton dissociation, and carrier tran

164 Upon blue light absorption, FAD is converted to the neutral radica

165 intaining stability and minimizing parasitic light absorption for integration on surfaces of semicond

166 are coordinated with the onset of measurable light absorption for photosynthesis.

167 otentially useful new dyes with panchromatic light absorption for solar energy conversion application

168 As a result, the increase in light absorption for transverse polarized light changes

169 ertical arrays of ZnO nanowires can decouple light absorption from carrier collection in PbS quantum

170 orbance and flux measurements differentiated light absorption from scattering for all materials.

171 the mixing state plays an important role in light absorption from volatile species.

172 In water-oxidizing photosynthetic organisms, light absorption generates a powerfully oxidizing chloro

173 n, accounted for 50-80% of the total visible light absorption (>400 nm) by solvent extractable BrC.

174 e use of a retro-reflective foil to optimize light absorption, high photocurrents up to 23.0 mA cm(-2

175 terned substrates possess broadband-enhanced light absorption, high quantum efficiency and desirable

176 Light absorption in conducting materials produces heatin

177 Light absorption in graphene causes a large change in el

178 step, we demonstrate electrical control over light absorption in metafilms constructed from dense arr

179 mplex II (LHCII) is the main responsible for light absorption in plants and green algae and is involv

180 coincides with the spectral range of minimal light absorption in sea water, raising intriguing questi

181 Analysis of light absorption in simulated structures, in tandem with

182 in snow, an important parameter affecting BC light absorption in snow.

183 location of the SLG that results in enhanced light absorption in the graphene at the excitation wavel

184 by enzymatic nitrate reduction initiated by light absorption in the nanoparticle.

185 more efficient photocatalysts with enhanced light absorption in the overall solar spectrum, improved

186 ain products that contribute to the enhanced light absorption in the secondary BrC.

187 ion, in which the photo-carrier generated by light absorption in the semiconductor might be transport

188 However, parasitic light absorption in the sun-facing front molecular layer

189 n fabricated, which even exhibited excellent light absorption in the visible region and greatly enhan

190 The compounds exhibit strong light absorption in the visible region, accompanied by s

191 markably strong photo-oxidants with enhanced light absorption in the visible region.

192 e (sExTTF) moiety, which exhibits an intense light absorption in the visible spectrum and a reversibl

193 tion of a wide-bandgap gap oligomer enhances light absorption in the visible spectrum.

194 This is because light absorption in tropical canopies is near maximal fo

195 ressed trap-assisted recombination, enhanced light absorption, increased hole extraction, efficient e

196 Full-wave electromagnetic simulations of light absorption indicated that the induced spatial grow

197 ructure of the intermediate, confirming that light absorption induces a sequential reaction path in w

198 r cells architectures that exceed Lambertian light absorption, integrated over the entire 300-1,200 n

199 rrower bandgap (<1.3 eV), thus extending the light absorption into the near-infrared (~1,050 nm).

200 Therein, upon proper design, the poor light absorption intrinsically featured by lanthanides i

201 Light absorption is followed by electron or hole injecti

202 The primary photochemical event upon light absorption is isomerization of the retinal chromop

203 is nondirectional and unpolarized, and that light absorption is isotropic.

204 Enhancing and spectrally controlling light absorption is of great practical and fundamental i

205 alyses: acidity, peroxide value, ultraviolet light absorption K(2)(3)(2) and K(2)(7)(0), carotenoids,

206 Upon red-light absorption, LAPD up-regulates hydrolysis of cAMP a

207 Integration of colloidal quantum dots in the light absorption layer can improve the responsivity of g

208 r bands could be responsible for the far-red light absorption leading to PS I photochemistry at wavel

209 This enhanced light absorption leads to a remarkably enhanced photores

210 rtificial photosynthetic systems with strong light absorption, long-lived charge separation and effic

211 semiconductors is still limited by their low light absorption, low charge mobility, high charge-carri

212 d lesion was used to guide reconstruction of light absorption maps at four wavelengths, and total hem

213 g the diatom frustules on the surface of the light-absorption materials is found to strongly enhance

214 nce of charged radicals in DNA strands after light absorption may cause reactions--oxidative or reduc

215 Particle light absorption measurements by a seven-wavelength aeth

216 Nonlinear light absorption mechanisms such as two-photon absorptio

217 alizing TiO2 materials for enhancing visible light absorption, narrowing band gap, and improving phot

218 e results provide insights into the enhanced light absorption near the band edge and good charge coll

219 l range of photodetection is reduced because light absorption occurs in the quantum dots.

220 ult, large BrC molecules dominated the total light absorption of aged biomass burning BrC.

221 The light absorption of methanol extracts showed a strong wa

222 In this work, the light absorption of methanol-extractable OC from prescri

223 Light absorption of PM2.5 water-soluble components at 36

224 molecules permits us to drastically enhance light absorption of QDs, while preserving good long-term

225 Thus, the light absorption of the fluorophore does not undermine t

226 CRY neutral radical is formed following blue light absorption of the oxidized flavin.

227 following attractions: 1) large and tunable light absorption of the polymer donor/polymer acceptor p

228 namic driving force for water oxidation, the light absorption of the polymer, and the aqueous dispers

229 s from the differential circularly polarized light absorption of the sample but is independent of con

230 ylethynyl donor group attachment expands the light absorption of these molecules to the 600-700 nm re

231 e aging via NO(3)(*) reactions increases the light absorption of wood tar aerosols and shortens their

232 w that O(3) oxidation in the dark diminishes light absorption of wood tar aerosols, resulting in high

233 1.3 electronvolts, CsSnI(3) enhances visible light absorption on the red side of the spectrum to outp

234 olar cells have been fabricated to enhance a light absorption path while maintaining a short carrier

235 ntroduction of Ag3PO4 on g-C3N4 promoted its light absorption performance.

236 heir interesting properties, such as visible-light absorption, photocatalytic activity and high diele

237 nge of time scales, which follow the initial light absorption process.

238 rtical distribution of leaf nitrogen and the light absorption profile.

239 Solid-state crystalline photocatalysts have light absorption profiles that are a discrete function o

240 lement gas-exchange model parameterized with light absorption profiles, we found that weaker penetrat

241 or improved photocatalysts by increasing the light absorption, promoting the charge separation and tr

242 Additionally, cell volume and light absorption properties increased in heated Cladocop

243 ence of a major biomass burning event on the light absorption properties of atmospheric brown carbon

244 idity is an important factor controlling the light absorption properties of BrC.

245 e only limited field studies to quantify the light absorption properties of specific types of primary

246 ctor, and (II) ancillary ligands to tune the light absorption properties of the dye and facilitate el

247 This work investigates the light absorption properties of the major OA components i

248 ments that show the effect of substituent on light absorption properties of the norbornadienes as wel

249 Even further control over the spectral light absorption properties of thin films has been achie

250 uch as quantum dots (QDs) have extraordinary light absorption properties, but their poor mobility and

251 yield of electron transfer and good visible light absorption properties.

252 n family with unknown function and ambiguous light absorption properties.

253 The ability to tune the light-absorption properties of chlorophylls by their pro

254 g glucose addition in AP-SWNTs treatment and light absorption property of SWNTs particles suggest tha

255 ow the carbide network with enhanced visible light absorption, providing high solar energy harvesting

256 n terms of chemical stability, toxicity, and light absorption range.

257 The light absorption ratio for nanometer GeSn/Al foil hetero

258 the light of the relevant properties, namely light absorption, reduced adhesion and friction, heat in

259 e investigate if the spatial distribution of light absorption relative to electron transport capacity

260 rve a concomitant strain-driven variation in light absorption--reminiscent of piezochromism--which we

261 on g-C3N4 significantly enhances the visible-light absorption, rendering them ideal for visible-light

262 try, has been used to manipulate fundamental light absorption, scattering, and emission processes in

263 ted hydrodynamically, detected optically (by light absorption/scattering), and immediately transferre

264 ed by up to +/-80nm, extending the protein's light absorption significantly beyond the range of known

265 arge transfer/recombination while optimizing light absorption, singlet fission and triplet rather tha

266 tioxidant capacity while reducing leaf area, light absorption, specific leaf mass, primary metabolite

267 otoconvertible between red and near-infrared light-absorption states.

268 coincident with the observations of enhanced light absorption, suggesting such oligomers as chromopho

269 ect on climate is predicting enhancements in light absorption that result from internal mixing betwee

270 borohydride reduction substantially reduced light absorption, the R(H(2)O(2)) values were largely un

271 nstrate that coatings on BC can enhance BC's light absorption, therefore many climate models simply a

272 s, solvent and substitution effects on their light absorption, thermal half-lives, photostationary st

273 (i) MS and HB both result from differential light absorption through a radial diattenuator, compatib

274 tely 80 water molecules flood rhodopsin upon light absorption to form a solvent-swollen active state.

275 d based on plasmonic metasurfaces of perfect light absorption to improve color performances such as s

276 obscures the mechanisms behind the efficient light-absorption-to-charge conversion process.

277 Light absorption triggers photoisomerization of the bili

278 20 nm) VO2 film, we demonstrate broadband IR light absorption tuning (from ~90% to ~30% in measured a

279 a promising photocatalyst with wide visible-light absorption up to 700 nm, but the fast charge recom

280 ave been focused on near-perfect and perfect light absorption using metamaterials spanning frequency

281 ch bind a protonated retinal Schiff base for light absorption, UV-absorbing rhodopsins bind an unprot

282 hat vertical temperature gradients caused by light absorption vary over 10-fold across species, reach

283 This biological example of efficient light absorption via a simple architecture of strongly a

284 The variability of PSII light absorption was independent of phylogenetic designa

285 ons (metal ion removal/binding; antioxidant; light absorption) was additive, with combinations provid

286 the "brown" carbon (BrC) budget and exhibits light absorption wavelength dependence close to the uppe

287 es in M.A.C. values associated with enhanced light absorption when polydisperse, laboratory-generated

288 fects current plant functioning, and dynamic light absorption, which coordinates with plant functioni

289 t of the entire indolizine pai-system during light absorption, which suggests these systems can be tu

290 y reach an electronically excited state upon light absorption while successively triggering the forma

291 usceptible to processes that lead to reduced light absorption, while larger-molecular-weight species

292 city and unprecedented visible/near-infrared light absorption with a lowest ever bandgap ~0.9 eV at r

293 ew, highly efficient pathway for integrating light absorption with bond formation.

294 Artificial photosynthesis relies on coupling light absorption with chemical fuel generation.

295 Near perfect light absorption with high quality factors are obtained

296 hotovoltaic devices, and for the coupling of light absorption with other functional properties.

297 microm-10 microm, and </=10 microm and PM2.5 light absorption with preterm PROM and gestational age a

298 mographic rates were related to variation in light absorption, with mortality increasing relative to

299 up to 8.5%, which is attributed to enhanced light absorption within the active layer and smooth hole

300 promising PDT agents due to intense visible light absorption, yet the majority are toxic even withou